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Gelatinization of Starch in Tilapia Feed Bharat Adhikari and Shijan Adhikari
ABSTRACT The aim of study was to observe the effect of different levels of starch gelatinization in feed
for Nile tilapia. Wheat was extruded with different moisture addition (20%, 25%, 30% and
35%), to tentatively obtain different degrees of starch gelatinization. Five different diets were
prepared one with raw wheat and remaining four with gelatinized wheat, using a pasta
machine. The degree of starch gelatinization of the diets were assessed by Differential
Scanning Calorimetry. All diets with wheat that had been extruded had completely
gelatinized starch. The diets (Diets 1-5) were fed to fishes in 10 tanks with 9 to 11 Nile tilapia
with a mean initial weight of 120 g for 30 days. Each diet was fed to fish in two tanks. The
tanks were supplied with freshwater from a recirculated aquaculture system with a mean
water temperature of 27°C. The fish were weighed at the beginning and at the end of the
experiment. Daily dietary dry matter intakes were assessed; chemical composition in initial
and final fish samples and diets were analyzed. Growth rates, feed conversion ratio, and
retention of dietary protein and energy were calculated.
The feed intake of fishes in each tank was on average 91 g per fish, which results in average
weight gain of 78 g per fish. Regression analysis showed that the retention of dietary protein
(p-value: 0.00821) and energy (p-value: 0.00821) were significantly related to second order
polynomial of dietary treatment, however feed conversion ratio and feed intake were not
significantly related. It was interesting to observe that at little addition of moisture as 20% in
extruding wheat gave complete gelatinization. This shows the advancement in engineering in
the field of feed manufacturing technology, which can be beneficial to feed producer and
farmers.
Keywords: Extrusion, Gelatinization, Nile tilapia, Moisture, Feed
1
Acknowledgements First of all, we would like to express our deepest sense of gratitude to our supervisor Dr.
Trond Storebakken and Co-supervisor Dr. Olav Fjeld Kraugerud at the IHA, who offered
their continuous advice and encouragement throughout the course of this thesis. We thank
them for the systematic guidance and great effort they put into training us in the scientific
field.
Besides our supervisors, our sincere appreciation goes to Mr. Ismet Nikqi, Mr. Bjørn Reidar
Hansen and Mr. Frank Sundby for guide and support with their immense knowledge present
in their field.
We are thankful to our senior Biswas Bajgai and colleagues Raju Rimal and Zulkernain
Akhter for the support and encouragement whenever we were in need.
We are indebted to Norwegian University of Life Science and Department of Animal and
Aquaculture Sciences at Ås for the education during our stay here as well as we thank who in
one way or other contributed in the completion of this thesis
Finally, we take this opportunity to express the profound gratitude from us to our beloved
parents.
Thank you all.
Bharat Adhikari (Master in Feed Manufacturing Technology)
Shijan Adhikari (Master in Feed Manufacturing Technology)
Norwegian University of Life Sciences (NMBU)
Ås, May 10, 2015
2
List of abbreviations °C Degree Celsius
DSC Differential Scanning Calorimeter
DG Degree of gelatinization
FAO Food and Agriculture Organization
FCR Feed Conversion Ratio
G Gram
H Hour
HCL Hydrochloric acid
L Liter
Min Minutes
Mg Milligram
MM Millimeter
Mg/dl Milligram/deciliter
MJ/Kg Mega joule/kilogram
NMBU Norges miljø- og biovitenskapelige universitet
RPM Revolution per minute
Wt. Weight
% Percentage
3
Table of Contents Acknowledgements 1
List of abbreviations 2
Introduction 1 Objective of study 1
Literature review 2 Wheat 2 Gelatinization of starch 2 Soybean Meal 3 Tilapia 4 Importance of tilapia farming 4
Materials and methods 5 Processing of wheat 5 Screw configuration of extruder 5 Experimental diets 5 Feed preparation 6 Fish and rearing unit 7 Feeding experiment 7 Ammonium Measurement 8 Chemical composition of diets and fishes 8 Degree of gelatinization 8 Blood sugar analysis 9 Fish growth performance, feed and protein utilization 9 Statistical Analysis 9
RESULTS 10 Degree of Gelatinization and Retrogradation 10 Survival, Growth and feed Performance 11
Feed Intake 11 Weight Gain 12 Whole body composition of Tilapia fed experimental diets 12 Feed Conversion Ratio 13 Protein Retention 13 Energy Retention 14 Ammonium measurement 14
Discussion 15
Conclusion 18
References 19
Appendix 25
4
List of figure Figure 1 Screw configuration of extruder 5
Figure 2 DSC diagrams for Diet 1 (with raw wheat) and Diets 2-4 10
Figure 3 Feed Intake vs. diet with second order trend 11
Figure 4 Weight gain vs. Diet plot 12
Figure 5 Feed Conversion Ratio vs. Diet with second order fitted trend 13
Figure 6 Protein Retention vs. Diet with second order fitted trend 13
Figure 7 Energy Retention vs. diet 14
Figure 8 Ammonium measurement at different time interval 14
List of Tables Table 1 Production of Nile Tilapia (Oreochromis niloticus) 4
Table 2 Wheat extrusion parameters 5
Table 3 Ingredients used in feed (g/kg) 6
Table 4 Proximate compositions of diets (g/kg) 8
Table 5 Average Growth and Feed performance in Tilapia 11
Table 6 Whole body composition of Tilapia 12
1
Introduction Carbohydrate is an inexpensive source of energy and is extensively being used in animal
feed. Carnivorous fishes, in general utilize dietary carbohydrate poorly, varying among
species (Shiau & Lei, 1999). However, without starch, other nutrients such as protein are
catabolized for energy (Li et al., 2013).Tilapia is an omnivorous fish which can withstand a
high level of dietary carbohydrate. Gelatinization will increase susceptibility for starch
degradation in digestive tract (Svihus et al., 2005), which consequently can increase the
digestibility in Tilapia too. This dissertation aims to seek the degree of gelatinization require
to obtain the maximum positive impact on growth and overall body performance.
Carnivorous fishes such as trout and European sea bass have poor utilization of carbohydrates
whereas omnivorous fishes such as tilapia can withstand on diet with 41 to 56 percent of
carbohydrate (Hemre et al., 2002a). However, the utilization of carbohydrates can be
enhanced by wet-heat treatment, which includes pelleting and extrusion. The limited water
content and temperature allow a small extent of gelatinization that makes pelleting less
efficient than extrusion (Svihus et al., 2005).
Although gelatinization increases digestibility, some study shows that it has negative impact
on growth and body performance in some animals such as broiler (Zimonja & Svihus, 2009).
Objective of study � The first objective was to find out effect of gelatinized starch on Nile tilapia
� The second objective was to reveal the weight gain, FCR, feed intake, protein and energy
retention in Nile tilapia fed different level of gelatinized starch and non-gelatinized
starch.
With hypothesis of positive impact of gelatinization in tilapia, an experiment was conducted
for 28 days. Observations were made on weight gain of the fishes fed with various degree of
gelatinized starch. Since, limited study has been carried out to identify the extent of
gelatinization for maximum growth this study aims to compare diets with different degree of
gelatinization with non-gelatinized starch.
2
Literature review Wheat Wheat (Triticum spp.) is a cereal grain cultivated worldwide. In 2010/11, world production of
wheat was 653.8 million tons that is estimated to increase to 716.6 million tons in
2013/14(Nation, 2015) The increase in production shows the demand and importance of
wheat in human consumption as well as in animal production. Wheat pentosans cause a
general inhibition of nutrient digestion affecting starch, fat and protein (Choct & Annison,
1992). Research by Miracle et el. (1977) and Stober et al. (1979) indicates that the
phosphorus in wheat and barley is more available than the phosphorus in corn because these
grains contain more total phosphorus than corn (Hayes et al., 1979). Starch yields of durra
wheat (Triticum durum) were between 24 and 33 % with an average of 29 % (Vansteelandt &
Delcour, 1999). The distribution of the two major starch molecules, amylose and
amylopectin, that are accumulated within the granules of wheat are formed of concentric
zones of alternating amorphous and semi-crystalline regions. Both polymers are made up
from chains of α (1→4)-linked glucose residues, but differ in the frequency of α (1 → 6)-
branches. The smaller amylose polymers contain few branches and make up 20–30 % of the
starch fraction, whereas the larger and heavily branched amylopectin molecules make up the
remaining part of starch (Båga et al., 1999). Wheat consists predominantly of starch (about
70-80% dry wt.), with lower amounts of protein (usually about 10-15% dry wt.), lipids (1-2%
dry wt.) (Shewry et al., 1997).
Gelatinization of starch Gelatinization is a process of breaking down the inter-molecular bond present in starch
applying heat and water. Starch has semi-crystalline structure with two components –
amylose and amylopectin. The bond between semi-crystalline structures irreversibly breaks
down as granules swells and burst with the application of heat and water. This leads amylose
molecules to leach out of the granules giving enzymes access to glycosidic linkage and
consequently increase digestion (Svihus et al., 2005).
All hydrothermal treatment used in feed processing results in gelatinization of starch, but the
extent varies. Pelleting results in range of 10-20% gelatinization and Expander in between
22-35% whereas extrusion may result in complete gelatinization. However, the extent of
gelatinization in extrusion depends upon extrusion conditions such as moisture, temperature
and processing conditions (Tester & Morrison, 1990). It has been shown that minimum water
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content of 30 % is required for a gelatinization of wheat (Svihus et al., 2005). Complete
starch gelatinization is generally achieved at 20-30% moisture and a temperature of 212oC
(Serrano & Agroturia, 1996).
Gelatinized starch is an effective energy source, since gelatinization increases starch
digestibility (Svihus, 2014), as well as protein and energy retention by catabolizing
gelatinized starch for growth and energy purpose instead of protein and energy (Peres &
Oliva-Teles, 2002). Gelatinized starch improves physical quality of feed by increasing
binding between particles in the ingredient mix.
Some of the research carried out regarding utilization of gelatinized carbohydrate has
produced contradict results. Positive impact of gelatinized starch on growth and body
performance were observed in rainbow trout when starch was 40% gelatinized (Abd El‐
Khalek et al., 2009), or in carp with 20% starch gelatinization (Kumar et al., 2008), or in
European sea bass at the ratio of 50% (Da Silva & Vázquez, 2014). However, negative
impact of gelatinized starch has been observed in broiler (Zimonja & Svihus, 2009) and
piglets (Serrano & Agroturia, 1996).
Soybean Meal Soybean meal is an extracted by-product of soybean oil. In 2010, world production of
soybean was 261.9 million tons that increased to 276 million tons in 2013 (FAO, 2015).
Apart from being easily available and inexpensive (Hardy, 2006), it has less phosphorous
which leads to low effluent waste (Lazzari & Baldisserotto, 2008). On the other hand it has
high protein content and good amino acid profile (Gatlin et al., 2007). This has made it
promising plant protein source. About 44 percent and 48 percent of crude protein is available
on solvent extracted soybean meal with and without hulls respectively (NRC, 1993).
Anti-nutrients such as trypsin inhibitors, lectins, oligosaccharides, antigens, saponins and
tannins are present in raw soybean. Although they have adverse effect on digestion and
nutrition, through heat process, the effect can be minimized or eliminated (Barros et al.,
2011). Further, despite of having good amino acid profile, soybean have limited amount of
essential amino acids such as methionine and cysteine that were reported to be deficient in
many fish species (Wilson, 2002). High amount of protein content in soybean has produced
promising results for its use on diets for species like common carp, tilapia, salmonoid, red
drum and marine shrimp (Alam et al., 2012). Different results indicate that it is possible to
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eliminate fishmeal totally or partially up to 75% with or without methionine supplementation
from commercial tilapia diets (Chou et al., 2004; El‐Saidy & Gaber, 2002).
Tilapia Tilapia (Oreochromis spp.) is the common name broadly applied to a group of cichlid fishes
native to Africa, the Mediterranean, and the Middle East. Tilapias are farmed “extensively”
in pond systems or more “intensively” in cages and tanks. Tilapia can be cultured in either
fresh or salt water in tropical and subtropical climates. Culture can be constrained in
temperate climates where production must be carried out in indoor tanks (Lim and Webster,
2006). Optimal growing temperatures are typically between 22°C and 29° C (Mjoun et al.,
2010). Annual production of tilapia is increasing rapidly and production of tilapia between
years 2007 - 2012 increases from 1862592 tons to 3197330 tons (Rakocy, 2005). China is the
top producer of tilapia in the world (FAO, 2015; Nemati Shizari, 2014).
Table 1 Production of Nile Tilapia (Oreochromis niloticus)
Year Quantity (ton) Year Quantity (ton)
2007 1862592 2010 2537461
2008 2061390 2011 2808741
2009 2240095 2012 3197330
Source: FAO FishStat (Rakocy, 2005)
Importance of tilapia farming Tilapia is known as `aquatic chicken` due to their high growth rate, adaptability to wide range
of environmental conditions and ability to grow and reproduce in captivity and feed on low
tropic level. It is thus no surprise that these fishes have become an excellent candidate for
aquaculture in tropical and subtropical regions. Tilapia has many attributes that make them
ideal candidate for aquaculture, especially in developing countries because of their fast
growth, tolerance to wide range of environmental conditions (such as temperature salinity,
low dissolved oxygen), resistance to stress and diseases (El-Sayed, 2006), availability of
genetic diversity, positive response to BioFlocs, omnivorous, variety of production modes
and polyculture (Fitzsimmons et al., 2011). The world’s total tilapia aquaculture production
in 2000 was 1.27 million metric ton and contributed about 3.6% of global total aquaculture
production (Gupta & Acosta, 2004).
5
Materials and methods Processing of wheat Prior to making experimental diets the main carbohydrate source wheat was extruded with
five different percentages of moisture. Wheat was ground in a hammer mill (E-22115 TF,
Muench - Wuppertal, Germany) with 1mm sieve and was passed in extruder machine. All the
extruded wheat pellets were dried for one hour, packaged, labeled and kept in cooler (2-5°C).
Table 2 Wheat extrusion parameters
Diet2 Diet3 Diet4 Diet5 Feeder, Main (Kg/h) 150.0 150.0 150.0 150.0 Extruder. Water (%) 0.0 7.5 15.0 25.5 Conditioner, stem (%) 11.9 12.3 11.9 10.8 Pressure at end plate (bar) 48.9 28.5 19.7 13.4 Drive Power (kW) 20.2 17.4 15.0 14.8 SME (Wh/kg) 134.4 110.5 91.2 84.1 Throughput 150.0 157.5 165.0 175.5 Extruder Section 1 94.2 78.4 56.8 67.9 Extruder Section 2 103.6 104.7 103.6 101.2 Extruder Section 3 131.5 128.6 119.2 123.7 Extruder Section 4 130.6 127.5 115.7 128.7 Extruder Section 5 130.3 120.8 95.4 109.1 Conditioner temperature (°C) 93.1 82.1 81.0 82.0 Screw speed (rpm) 502.0 502.0 501.0 348.0 Torque absolute (Nm) 384.1 331.0 286.7 404.8 Torque real (Nm) 88.3 76.1 66.0 93.1 Temperature at endplate (°C) 127.8 111.2 89.0 91.9 Knife speed (rpm) 547.0 547.0 547.0 547.0
Screw configuration of extruder Fortek Mild SME input Total Front
Length
40 20 60 60 80 80 80 100 20 20 120 100 80 60 60 60 60 80 80 1260 R R R R R R R R R L Polygon R R R R R R R R Figure 1 Screw configuration of extruder
Experimental diets Five different complete plant based feeds were prepared for experiment. The ingredients
present in feeds were soybean meal, wheat, corn gluten, rapeseed oil, methionine, taurine,
6
phenylalanine, vitamin c 35%, yttrium oxide (Y2O3), mono-calcium phosphate (MCP),
sodium alginate and premix (Table 3).
Table 3 Ingredients used in feed (g/kg)
Ingredients Amount (g/kg) Soybean mealb 440 Corn glutenc 65 Wheatd 410 Rapeseed oile 37 Methioninef 5.0 Phenylalanineg 0.9 Taurineh 1.5 Monocalcium phosphatei 10 Premixk 10 Vitamin C -35%l 0.1 Yttrium oxide (Y2O3)m 0.8 Sodium alginateo 20
Feed preparation Five different feeds were prepared in feed lab of NMBU with ten kilo of feed in each batch.
Preparation of diets began with grinding of wheat pellet, soybean meal and corn gluten by
using 1mm screen (sieve) (Retsch Gmbh Retsch-Allee 1-5, 42781, Haan, Germany). All the
ingredients were correctly weighed and mixed uniformly. To make a mixing homogenous the
spiral dough mixer (Moretti Forni Grain, Italy) was used for about 20 minutes. During the
mixing 3ℓ cold water (30% of total feed weight) and 1ℓ rapeseed oil was added slowly and
continuously in feed one and two (0 and 20% moisture added during extrusion). 3.5 l (35% of
total feed weight) and one liter of rapeseed oil was added in Diets 3, 4 and 5 (25, 30, and 35%
moisture added during extrusion). The different water addition was due to differences in
b Soybean meal, Denosoy, Denofa, Fredrikstad, Norway. c Maize gluten, Cargill 13864. d Felleskjøpet, Norway e Food grade, Eldorado, Oslo, Norway. f Adisseo Brasil Nutricao Animal Ltda, Sao Paulo, Brazil. gAdisseo Brasil Nutricao Animal Ltda, Sao Paulo, Brazil h Taurine-JP8, Qianjiang Yongan Pharmaceutical Co., Ltd., Hubei, China. i Taurine-JP8, Qianjiang Yonga Pharmaceutical Co., Ltd., Hubei, China. k Contents per Kg: Vitamin A 2500.0 IU; Vitamin D3 2400.0 IU; Vitamin E 0.2 IU; Vitamin K3 40.0 mg; Thiamine 15.0 mg; Riboflavin 25.0 mg; d-Ca-Pantothenate 40.0 mg; Niacin 150.0 mg; Biotin 3.0 mg; Cyanocobalamine 20.0 g; Folic acid 5.0 mg; Pyridoxine 15.0 mg; Vitamin C: 0.098 g (Stay-C 35, ascorbic acid phosphate, DSM Nutritional Products, Basel, Switzerland); Cu: 12.0 mg; Zn: 90.0 mg; Mn: 35.0 mg; I: 2.0 mg; Se: 0.2 mg; Cd = 3.0 g; Pb = 28.0 g; total Ca:0.915 g; total K 1.38 g; total Na 0.001 g; total Cl 1.252 g; l Stay-C 35, ascorbic acid phosphate, DSM Nutritional Products, Basel, Switzerland. l Trouw Nutrition, LA Putten,Netherland m Metal Rare Earth Limited, Jiaxing, China.
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water absorption in the differently extruded wheat preparations. All the feed dough was
transferred to a pasta machine (P55DV, Italgy, Carasco, Italy) and was properly conditioned
and mixed then cut in pellet at 3.5 mm die size by using the knife at the edge of the craft
opening. The prepared feed was kept on drier at 50°C for seven h, cooled to room
temperature and stored at 2-5oC.
Fish and rearing unit The experiment was conducted at Fish Nutrition Laboratory (NMBU) from 21st October to
17th November 2014. The experimental Nile tilapias (generation 12th of selection, donated by
Genomar AS, Norway) were hatched at same laboratory and fed on a commercial diet until
the individual body weight was approximately 0.1 kg. For the experiment 10 indoor rearing
tanks (70 cm× 50 cm × 50 cm) were chosen. The tanks were supplied with freshwater from a
recirculation system, with the water level of 50 cm in each tank. Each tank was stocked with
10 fishes. Tanks were kept in 24 hour light system during whole experiment, and the water
temperature was 28°C.
First all the tanks and pipes were cleaned and fishes to be used in trial were selected from
large population. Fishes were netted with minimum disturbance and anesthetized (Tricanine
methanesulfonate-MS-222, 0.1 g/l water, buffered with NaHCO3, 0.1 g/l
water, Western
Chemical Inc. Washington USA). Fishes were weighed individually. At the same time ten
fishes were randomly taken from same population, weighted and kept in freezer at -20°C for
initial whole body composition analysis.
At day 28 of feeding trial fishes of each tanks were weighed, liver samples and faeces from
last 15 cm of intestine was taken (incision was given from dorsal part of operculum to base of
pelvic fin, similarly from dorsal part of operculum to caudal part of anal fin via upper lateral
line scale opening abdominal cavity) by firmly squeezing intestine and remaining part of
intestinal content was cleaned. After that five fishes from each tank were kept for final whole
body composition analysis. At the same time whole-blood glucose was analyzed.
Feeding experiment The five different feeds were fed to the fishes. Different in sense of percentage of moisture
added while extruding wheat. In 10 tanks ten fishes were kept with biomass 1170gram (±10).
Feeding one feed for two tanks was done and time of feeding was 8:15 to 9:15 in the morning
and 20:15 to 21:15 in the evening every day for 28 days, with electrically driven band
feeders. The uneaten feeds were collected from water outlet while feeding and 30 minutes
8
after finishing feeding. Uneaten feed from morning and evening was collected and dried at
105°C overnight. Dietary dry matter was calculated from the difference of daily fed feed and
uneaten feed after dried.
Table 4 Proximate compositions of diets (g/kg)
Parameters Diet1 Diet2 Diet3 Diet4 Diet5 Dry matter 57.9 69.4 80.8 59.1 55.3 Energy (MJ/Kg) 18.5 17.8 17.6 18.4 18.4 Protein 292 280.7 263.1 295.9 291.1 Carbohydrate 280.4 277.5 278 271.4 261.7 Fat 53.2 36.3 32.2 31.7 36.2 Ash 53 51 50 54 54
Ammonium Measurement Ammonium concentration measurement in tanks water was started one hour after last meal
(10:00am) and was continued in every two hours interval till 4:00pm. The measurement was
done from inlet and outlet water of tank on day 28. The detail procedure of ammonium
calculation is in appendix.
Chemical composition of diets and fishes Diets and fish body composition was done by proximate analysis. Sampled fishes were taken
from -20 °C freezer and were cut in small piece and were homogenized in a grinder. The
ground fish was freeze dried for a week and then samples were again ground with dry ice.
The dry matter of fish was determined after the loss of moisture from the sample when heated
at 105°C for 20 hours in an oven. Crude protein was analyzed by Kjeltec auto 1035/1038
systems. Energy of both fish and feed was determined by Parr bomb calorimeter whereas
HCL hydrolysis followed by diethyl ether extract method was used to determine crude fat.
Ash content was analyzed by heating at 500°C in muffle furnace.
Degree of gelatinization Degree of gelatinization was determined as per the procedure described by Zimonja and
Svihus (2009). Feed samples were ground to 0.5 mm. They were assessed for gelatinization
by differential scanning calorimetry. One part sample was mixed with two parts of water. The
suspension was slowly stirred and for uniform mixing, suspension was run in vortex mixer
for 2 min. The suspension was then allowed to stand for 1 h for equilibration purpose. After 1
h, approximately 130 mg sample was heated from 0 to 160oC with an increase of 5oC per min
on a Metter DSC 30S (Metter Toledo AG, Schwerzenbach, Switzerland). Silicon oil was used
9
as reference. Determination of enthalpy values was carried out by computer integration of
inverse peaks. Degree of starch gelatinization was calculated based on the difference in
enthalpy between sample before and after feed processing. The measurements were
conducted in duplicate. Since the four samples containing less than 30 percent of moistures
were completely gelatinized so, the fifth sample is assumed to get gelatinized and is removed
during analysis.
Blood sugar analysis Blood sugar was analyzed by rapid test kit (ACCU-CHEK® Compact Plus assembled for and
distributed in the U.S.A. by Roche Diagnostics, Indianapolis, IN, made in Ireland Roche
Diagnostics 9115 Hague Road Indianapolis, IN 46256) by piercing fish anterior to base of
caudal fin around lateral line scale. Blood was dropped in black area of test strip and after
five seconds blood sugar was displayed in screen in mg/dl.
Fish growth performance, feed and protein utilization Feed conversion ratio:(FCR) = Dietarydrymatterintake(g)/weightgain(g) Dietary dry
matter intake (g)/weight gain (g).
Protein Retention (%) = 100 ×final protein content in fish (g) − initial protein content in fish (g)
Protein intake by fish (g)
Energy Retention (%) = 100 ×final energy content in fish (kj) – initial energy content in fish (kj)
Energy intake by fish (kj)
Statistical Analysis Results were analyzed statistically by 1st and 2nd regressions, and the model giving best fit
was chosen. The plots were made in Microsoft Excel, and significance levels were calculated
in SAS version 9.4, SAS Institute Inc., Cary, NC, USA. Statistical significance is indicated
for p < 0.05.
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RESULTS Degree of Gelatinization and Retrogradation All starch present in extruded wheat were complete gelatinized as seen in DSC curve.
Further, there were not any fluctuations in the curve at temperature below 25°C, which
signifies that retrogradation phenomenon during storage, was not present in experimental
diets fed to fish.
Diet 1 Diet 2
Diet 3 Diet 4
Figure 2 DSC diagrams for Diet 1 (with raw wheat) and Diets 2-4
Incomplete gelatinization of starch was seen for Diet 1 that was not extruded (Figure 1).This
is indicated by the uptake of energy seen at approximately 69oC. Visible fluctuations in
energy in the temperature range of 50°C - 90°C was not observed for Diets 2-4, signifying
complete gelatinization of starch in these diets.
11
Survival, Growth and feed Performance All the fishes survived during experiment. The growth and feed performance are presented in
Table 5.
Table 5 Average Growth and Feed performance in Tilapia
Parameters Diet1 Diet2 Diet3 Diet4 Diet5
Initial weight (g) 117.3 124.0 124.9 112.7 118.5
Final weight (g) 193.3 222.3 188.0 190.3 193.4
Weight gain (g) 76.0 98.3 63.1 77.6 75.0
Feed intake 121.9 101.3 65.8 81.5 84.4
Feed Conversion Ratiop 1.63 0.99 0.99 1.03 1.08
Protein retention (%) 32.0 53.7 56.4 53.3 49.6
Energy Retention (%) 19.3 36.9 35.7 39.6 32.6
Feed Intake Fishes seem to prefer Diet 1, which was not gelatinized (Table 1, Figure 2). It has higher
(1218.5 g) level of feed intake than other diets. The model fitted to see the effect of diet on
feed intake has suggested that the diets have significant effect on Feed Intake (p-value:
0.021). The model has described around 67 percent of variation present in it.
Figure 3 Feed Intake vs. diet with second order trend
p DM intake (gm) / Weight Gain (gm)
y = 75.527x2 - 538.77x + 1686.7R² = 0.66921, p < 0.05
400.00
600.00
800.00
1000.00
1200.00
1400.00
1600.00
0 1 2 3 4 5 6
Feed
Inta
ke
Diet
Feed Intake
12
Weight Gain Weight gain ranged from 63.1 to 98.3 g per fish with least weight being 63.1 g for Diet 3 and
the highest 98.3 g for Diet 2 (Table 1). However, diets did not describe the variation present
in weight gain during experiment significantly (p-value: 0.913). A model fitted with weight
gain and diet is plotted in Figure 4.
Figure 4 Weight gain vs. Diet plot
Whole body composition of Tilapia fed experimental diets Average final composition of the whole body of tilapia was modeled with second order
polynomial of diets. Although models are not significant the average final protein is found
significantly greater than the initial protein (Table 2).
Table 6 Whole body composition of Tilapia
Parameters Initial Diet1 Diet2 Diet3 Diet4 Diet5
Dry matter (g/kg) 293.7 287.8 332.7 297.3 306.6 296.0
Energy (Mj/kg) 23.5 22.7 23.5 23.3 23.8 23.3
Protein g/kg 504.5 520.2 518.2 513.6 514.1 525.8
Fat g/kg 285.8 241.0 287.1 297.3 321.2 285.8
Liver lipid g/kg 265.9 335.5 291.3 382.4 269.6
Liver glycogen g/kg 298.9 314.1 314.3 294.9 346.1
Blood sugar mg/dl 4.26 5.42 5.64 4.92 6.04
y = 5x2 - 43.9x + 848.2R² = 0.0257, p > 0.05
450
550
650
750
850
950
1050
0 1 2 3 4 5 6
Wei
ght G
ain
Diet
Weight Gain
13
Feed Conversion Ratio FCR of tilapia fed experiment Diets 2 and 3 (Table 5, Figure 4) tended to be utilized most
efficiently, since these diets have the lowest FCR (0.99). The effect of diet explained around
48 percent of variation in FCR. However, the model is not significant (p-value: 0.1).
Figure 5 Feed Conversion Ratio vs. Diet with second order fitted trend
Protein Retention The diets used during the experiments are responsible for more than 74 percent of variation
present in protein retention (Figure 5). The fitted model as well as diet and its squared terms
are significant (p-value: 0.008). Protein retention ranges from 39.9 to 56.4 with average value
of 49.0.
Figure 6 Protein Retention vs. Diet with second order fitted trend
y = 0.101x2 - 0.7117x + 2.1633R² = 0.48191, p > 0.05
0.00
0.50
1.00
1.50
2.00
2.50
0 1 2 3 4 5 6
FCR
Diet
Feed Convertion Ratio
y = -4.0483x2 + 27.765x + 10.23R² = 0.74656, p < 0.05
0.00
10.00
20.00
30.00
40.00
50.00
60.00
70.00
0 1 2 3 4 5 6
Prot
ein
Rete
ntio
n
Diet
Protein Retention
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Energy Retention A similar effect of diet on energy retention is visible as in the case of protein retention
(Figure 6). Almost 70 percent of its variation is explained by the second order polynomial of
diets used. The model is significant (p-value: 0.016).
Figure 7 Energy Retention vs. diet
Ammonium measurement Ammonium concentration in water was found to reach peak after 4 hours of meal and start
decreasing thereafter for all diets.
Figure 8 Ammonium measurement at different time interval
y = -3.1553x2 + 21.861x + 1.9416R² = 0.69416, p < 0.05
0
5
10
15
20
25
30
35
40
45
0 1 2 3 4 5 6
EnergyRetention
0.70.80.9
11.11.21.31.41.51.61.7
10am 12pm 2pm 4pm
Amm
oniu
m
Time
Diet1 Diet2 Diet3 Diet4 Diet5
15
Discussion For optimal utilization of starch by Nile Tilapia present in feed, the main carbohydrate
ingredient- wheat was extruded in different moisture level (20%, 25%, 30%, 35%). The
purpose was to get different percentage of gelatinization but all were complete gelatinized.
We couldn’t get the accurate estimate because extruded wheat was not available for DSC.
Wheat samples kept in cooler room were thrown away while renovating the room without
informing us.
In extruding wheat from feed technology point of view, extruder machine didn’t work
efficiently while extruding wheat below 20% moisture addition, so the starting was 20%. As
the moisture was increased temperature, pressure and shear was decreased and viscosity was
increased. At least addition of moisture (7% steam addition) gave complete gelatinization,
which is good achievement in regular practice.
Extruded diets were examined in differential scanning calorimeter to determine percentage of
gelatinization and found that all the starch were complete gelatinized. The result from
Owusu-Ansah et al. (1983) supports the result, who found that at 90 rpm maximum
gelatinization occurred at temperature 100°C and feed moisture 23%. Case et al. (1992)
reported that wheat flour with 28% moisture was 86% gelatinized whereas corn meal, corn
starch and wheat starch with 35% moisture were 86%,85% and 55% gelatinized respectively.
The result is contradict with Gomez and Aguilera (1984) who found that, maximum
gelatinization was observed at about 28-29% moisture. Below 20% moisture, dextrinization
becomes predominant during high- shear cooking-extrusion. The result of Da Silva et al.
(1996) shows that, in 35% moisture, percentage of gelatinization is 10.6 ±0.3 which support
Gomez & Aguilera (1984).
From previous research we found that gelatinization is limited in feed with low moisture, for
complete gelatinization moisture should be high. From the feed technologist point of view it
is good achievement that we got complete gelatinization in 20% moisture and the feed is well
utilized by fish.
Five feeds were fed to Nile tilapia for 28 days in which weight gain was higher in diet two
(20% moisture). The result is supported by Takeuchi et al. (1994) who found, increase in the
level of gelatinization of diet increases the growth in tilapia and grass carp as well as
improves the nutritive value of diet. There is also another finding that says carnivorous fish
16
show growth promotion when gelatinized starch are included at low level (Hemre et al.,
2002b). In contrast, research conducted by Peres and Oliva-Teles (2002) on European Sea
bass (Dicentrarchus Labrax) found that weight gain, specific growth rate and feed intake was
low in gelatinized starch feed than raw starch.
In addition diet two fed fish have low FCR value, the improvement was not seen in other
diets. There is no any explanation to this and this should be looked in further research. Diet
one was not gelatinized and diet 3,4,5 were complete gelatinized, which support the study of
Amirkolaie et al. (2006), who explained that, growth was higher and FCR was lower for fish
fed the gelatinized starch compared to those fed the native starch. Increasing the starch
content of the diets resulted in an increased growth and improved FCR. Similarly, the study
of Booth et al. (2000) says that, FCRs were poorest in fish fed both un-steamed diets and
markedly improved for fish fed both the steamed and extruded diets. According to Pfeffer et
al. (1991) replacing untreated maize or starch in the diets by the respective extruded maize or
starch caused significant reductions of consumption and gain in trout. Feed conversion ratios
were improved concurrently, as these reductions were more pronounced in consumption than
in gain,
The average weight gain/day of fish fed with diet one, four and five is about 2.7gm while the
gain is quite high which is at around 3.52 for the fish fed with diet two. Inverse to the diet
two, weight gain of fish fed with diet three is much less (2.28).
Glucose availability in the blood is increased with the increase level of moisture in extrusion
except diet4; diet5 shows the highest value as compared to other diets. This shows that starch
in the feed was utilized more efficiently as it was gelatinized but there is no obvious
explanation to connect the link between increases in moisture while extruding increased
availability of glucose and this should be looked in further research. Protein and energy
retention was higher in diet2 and lower in diet1 fed two times a day.
In the experiment water temperature was 28°C and PH7. According to Azaza et al. (2008)
experiment conducted in four different temperature (22,26,30,34) and PH range from 6.98 to
7.41 found increase in feed consumption, mean body weight and decreased FCR in fishes
kept in 26°C and 30°C than 22°C and 34°C. The experiment is also supported by Coyle et al.
(2004) who found 100% survival and high diet acceptance in water temperature 27.4°C and
PH8. This shows that temperature and PH were within suitable condition for the growth of
Nile tilapia.
17
The term retro-gradation is used to describe the changes that occur upon cooling and storage
of gelatinized starch (Fredriksson et al., 1998). Retrograded starch are resistance to digestion
(Haralampu, 2000). From the result we found that our starch were not retrograded. The
practical importance of non-retrograded feed is its fresh, pleasant, nutritive and digestible.
18
Conclusion Complete gelatinization was achieved by the lowest water supplementation to wheat. No
significant effects of water addition in extrusion of wheat were observed for growth or feed
conversion. Thus, 20% water addition seems sufficient for extruding wheat for use in tilapia
feed. The improved feed intake, retentions of protein and energy observed by comparing the
use of non-gelatinized wheat (Diet 1) with that obtained by extruding with 20% water (Diet
2), illustrates the advantage of using gelatinized starch in tilapia feed.
19
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Appendix
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